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Let's say I have "peachz" as a string, and "eachzp" and "pahezc" as attempts used for comparison.

I'm looking for an algorithm that outputs the level of disorder of the array, regarding the relative order of the occurrences. In the following example I describe the problem with my current algorithm. I'm summing up the differences in the attempt position of each character against the ones on the original string.

Here's an example image:

"eachzp" has the same order of characters, except for the P. Because P has moved to the first position, every other character is seen as being one position out of place. "eachzp" will output a disorder degree of 10, while the totally scrambled "pahezc" attempt will output 8. This is incorrect. Things like Hamming or Levenshtein distance do not take these "order sequences" into account either.

My question is: Is there an algorithm I can use to output the disorder/similarity of the strings, considering the relative order of their characters?

(This should not be dictionary-related, since the strings aren't words and do not have any lexical meaning. If it helps, characters will are also be unique on each string.)


/edit: I'll try to explain my situation in a different way, trying to further detail it:

  • The strings are always of the same length

  • The strings have always the same chars (eg. if the original were "ors", other strings could only be "ors", "osr", "sor", "ros", "sro" or "rso" - same length and same chars)

  • The chars are always unique on each string

  • The strings are not words and have no lexical meaning at all

  • I need the algorithm to take the order sequence into account. If the original string is "peachz", "eachzp" is ordered almost exactly in the same way - only "p" is out of place. This should be more similar to "peachz" than "pahezc", that is much more scrambled, and in all directions (i feel this "direction" notion could be relevant to the solution).

  • "eapchz" should also be less scrambled than "eachzp". On both situations only the letter "p" is out of place, but it has moved a shorter distance on "eapchz".

All help is appreciated. thanks

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3 Answers 3

This sounds like the problem of counting inversions in an array; at the link you'll find descriptions of an O(n log n) divide-and-conquer algorithm similar to mergesort.

In the inversions problem, you have an array like 1 3 2 5 4 and want to measure how far out of order it is compared to 1 2 3 4 5. So 1 2 3 4 5 is the analog to your "peachz", and if we assign 1 to 'p', 2 to 'e', etc., they're the same problem. An inversion is any pair of elements that are out of order (not necessarily adjacent elements).

It's possible you want a measure other than inversion count -- my best guess would be rotation count, where a rotation removes an element from one position and sticks it somewhere else. For example, "eachzp" is just one rotation away from "peachz". I think you could count rotations with an O(n^2) dynamic-programming algorithm like the Levenshtein distance one, though I haven't checked this..

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Thanks. I tried inversion count and it outputs exactly the same normalized score that the algorithm I currently use (the one explained above), for every case. So, wasn't able to get an improvement from there. I will check rotation count next. I have edited the opening post with a better detailed explanation of what I need, if you have any further ideas please do share 'em. :) –  baderous Nov 11 '10 at 14:20
That's quite surprising -- does it seem to be the same in general? (Or did you try only the examples above? I'm just wondering.) OK, I have one amendment to propose: since you've added that the distance of the rotation matters, you need to decide at what point a big rotation costs more than two small ones, and turn my measure into a sum of rotation costs. –  Darius Bacon Nov 11 '10 at 20:11
It's the same in general :) Imagine a string with 10 inversions on a maximum of 30, the above algorithm would score 20 in a maximum of 60. When normalized, it is the same output. I have altered my original solution to include a "maximum penalty", reducing the influence of outliers, but it is still nothing "ideal". –  baderous Nov 16 '10 at 9:37

Edit: Completely new algorithm.

It seems to me like your notion of "disorder" corresponds to how readable the scrambled string is compared to the original. A decent measure of readability would be to find unscrambled substrings and then see what the overall order of the substrings is.

  1. Find all of the substrings of the scrambled string of maximal length that match the original string and store them in an array in the order found. Note: since each letter only appears once, the substrings will be disjoint.
  2. Let the "fragmentation score" be the number of maximal substrings.
  3. Let the "continuity score" be the sum of the squares of the lengths of the substrings.
  4. For each substring, score it by comparing it to the overall order of the substrings (add up how many precede it that should and how many follow it that should). Let the string's "order score" be the sum of all of the scores of the substrings.
  5. We now have a three-dimensional score. Compare strings by first comparing fragmentation score, if they are equal compare continuity score, if they are equal compare order score. Lower fragmentation scores are less scrambled, higher continuity and order scores are less scrambled.

Example: "acpehz" has frag, cont, and order scores 3, 12, 4.

By this method, we have "peachz" < "eachzp" < "pahezc", as desired.

The only obvious limitations I can think of for this algorithm are that it's probably going to be very slow and "eachzp" is less scrambled than "pezach" even though you might think of them as equal since "only one letter is out of order".

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that "maximal and minimal score" was also true for the "bad algorithm" i described. This behaves "as badly" as my original one. If you try my example attempts "eachzp" (which has the same order sequence for all chars except for "p") and "pahezc" (scrambled in all directions, with no resemblance to the original one) you get 20 out of 30 for "eachzp", and 22 out of 30 for "pahezc". Although our algorithms say otherwise, we know that "pahezc" is trivially far less similar to "peachz" than "eachzp". –  baderous Nov 10 '10 at 17:18
I disagree that it's "trivially far less similar". There are numerous methods of measuring disorder, and clearly our intuitions do not agree about what the "natural" one is. Though I probably should have made sure that my algorithm did want you wanted before posting it. –  Max Nov 10 '10 at 21:58
I have completely updated my algorithm. –  Max Nov 10 '10 at 22:59
Thanks, that was useful. I feel I'm now closer to the solution. I also need "eachzp" to be more scrambled than "pezach" because the "one letter out of order" moved a shorter distance, but that's my fault for not having specified it. Would upvote if I could –  baderous Nov 11 '10 at 10:42

If I understand your question correctly, you are looking for the Kendall-Tau distance metric. You can read about it here.

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Thanks. I think that's no different from counting inversions, like the answer Darius Bacon gave. This one uses bubble sort instead of merge sort, but the output would be equivalent. Please check that discussion for details on why it doesn't improve the current situation –  baderous Nov 22 '10 at 15:57

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